Measurement instrument and measurement method
A measuring apparatus for measuring reliability against jitter of an electronic device, including: a jitter tolerance estimator operable to estimate a jitter tolerance of the electronic device based on an output signal output from the electronic device according to an input signal input through a transmission line of which the transmission length is shorter than a predetermined length so that it does not generate a deterministic jitter; a jitter tolerance degradation quantity estimator operable to estimate a quantity of degradation of the jitter tolerance which deteriorates by the deterministic jitter caused in the input signal by transmission through the long transmission line when the input signal is input into the electronic device through the transmission line, of which the transmission length is longer than a predetermined length so that it may cause the deterministic jitter; a system jitter tolerance estimator operable to estimate a jitter tolerance of the electronic device and a jitter tolerance of a system including the long transmission line and the electronic device based on quantity of degradation of the jitter tolerance, is provided.
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The present application is a CIP application of PCT/JP03/01523 filed on Feb. 14, 2003 which claims priority from PCT/US02/05901 filed on Feb. 26, 2002 and U.S. Ser. No. 10/265,349 filed on Oct. 4, 2002, the contents of which are incorporated herein by reference.
BACKGROUND OF THE INVENTION1. Field of the Invention
The present invention relates to a measuring apparatus and a measuring method for measuring an electronic device. More particularly, the present invention relates to a measuring apparatus and a measuring method that measure a jitter transfer function, a bit error rate and jitter tolerance of the electronic device under test. The present application also relates to the United States patent application described as below.
2. Description of the Related Art
Jitter testing is an important item to a serial-deserial communication device. For example, Recommendations and Requirements from International Telecommunication Union and Bellcore ((1) ITU-T, Recommendation G.958: Digital Line Systems Based on the Synchronous Digital Hierarchy for Use on Optical Fibre Cables, November 1994, (2) ITU-T, Recommendation O.172: Jitter and Wander Measuring Equipment for Digital Systems Which are Based on the Synchronous Digital Hierarchy (SDH), March 1999, (3) Bellcore, Generic Requirements GR-1377-Core: SONET OC-192 Transport System Genetic Criteria, December 1998) define measurements of jitter tolerance, jitter generation and jitter transfer function.
Therefore, VLSIs for serial communication have to satisfy the values described in the above specifications. Especially, in the jitter tolerance measurement of a deserializer, (a) a sinusoidal jitter is added to zero-crossings of an input bit stream, then (b) the deserializer samples the serial bit stream at times in the vicinity of decision boundaries (sampling instants) and outputs the serial bit stream as parallel data. (c) one port is connected to a Bit Error Rate Tester and its error rate is calculated. (d) This decision boundary or sampling instant has to be obtained from a recovered clock or a clock extracted from the data stream, in which the zero-crossings have jitter. Thus, it is apparent from the above that the jitter tolerance measurement is one of the most difficult measurements.
First, a conventional measuring apparatus that measures a jitter transfer function of the device under test is described.
The deserializer performs serial-parallel conversion for input serial bit stream so as to output the converted data as recovered data of a plurality of bits. The data clock of the pattern is subjected to phase modulation by the sinusoidal wave supplied from the network analyzer.
A recovered clock in the recovered data output from the deserializer is compared to a reference clock in phase by being mixed with the reference clock.
The network analyzer measures the jitter transfer function of the deserializer based on phase noise spectra in the digital signal input to the deserializer and phase noise spectra in the recovered data. In a case of measuring the jitter transfer function based on a ratio of the phase noise spectra, however, the phase noises in a region other than the edges of the waveform are included. These phase noises prevent the high-precision measurement of the jitter transfer function.
Next, discuss the measurement problem associated with periodic sampling. The jitter analyzer samples one sample per M periods of the input data. The jitter analyzer also performs each sampling at a timing shifted by a small phase. That is, assuming the period of the input data to be T, the sampling period of the jitter analyzer is MT+TES. Since both the input data and the output data are periodic waveforms having a period of multiples of T, the result of the sampling are substantially equivalent to that obtained in a case of sampling at a sampling period TES.
The jitter analyzer calculates a ratio of the instantaneous phase spectra of the input data to the instantaneous phase spectra of the output data based on the sampling result and then measures the jitter transfer function of the deserializer based on the thus calculated spectra ratio. However, the jitter analyzer performs the sampling at the sampling period of MT+TES and extracts data equivalent to the data of one period. Thus, it takes long time to measure the jitter transfer function.
Moreover, the jitter analyzer generates the waveform equivalent to one period data from approximately MT/TES samples. Therefore, it is difficult to measure the fluctuation of the period between adjacent edges in the waveform of the input data or the output data. The period fluctuation in the waveform generated by the sampling is a mean value of the period fluctuations between the adjacent edges in M periods of the input data or the output data. Therefore, the jitter analyzer cannot precisely measure the instantaneous phases of the input data and the output data, so that it is difficult to precisely measure the jitter transfer function.
Next, a conventional method for measuring the bit error rate and a conventional method for measuring the jitter tolerance are described. According to an eye-diagram measurement, the performance of the communication device can be tested easily.
The jitter tolerance measurement is an extension of the bit error rate test.
Moreover, in the jitter tolerance measurement, while the applied jitter amount is increased with the jitter frequency ƒJ fixed, the minimum applied jitter amount that causes the occurrence of the bit error is obtained. For example, in order to perform the bit error rate test for a 2.5 Gbps serial communication device by using a pseudo-random binary sequence having a pattern length of 223-1, the test time of 1 sec is required. Therefore, in order to measure the jitter tolerance by changing the jitter amplitude to be supplied 20 times, the test time of 20 sec is required.
Timing degradation of the input bit stream as well as amplitude degradation increases the bit error rate. The timing degradation corresponds to the horizontal eye opening in the eye-diagram measurement, while the amplitude degradation corresponds to the vertical eye opening. Therefore, by measuring the degrees of the timing degradation and amplitude degradation, the bit error rate can be calculated. Please note that the jitter tolerance measurement corresponds to the horizontal eye opening in the eye-diagram measurement. For example, degradation of the amplitude of the received signal of ΔA=10% corresponds to the reduction of the signal-to-noise ratio of 20 log 10(100-10)/100=0.9 dB Therefore, the bit error rate increases by 0.9 dB. As for the timing degradation ΔT, the similar calculation can be performed. Please note that the % value of the ratio and the dB value are relative values, not absolute values. In order to obtain an accurate value of the bit error rate, calibration is required. Here, the definition of ΔA and ΔT by J. E. Gersbach (John E. Gersbach, Ilya I. Novof, Joseph K. Lee, “Fast Communication Link Bit Error Rate Estimator,” U.S. Pat. No. 5,418,789, May 23, 1995) is used. The apparatus disclosed in the above patent uses the following equation
to calculate an instantaneous bit error rate from ΔA, ΔT, a local clock period T and the maximum value A of the samples at the optimum sampling instants. However, the aforementioned apparatus merely provides a method for estimating the bit error rate by measuring the timing degradation by a Gaussian noise jitter. The apparatus described in the aforementioned patent obtains a histogram of data edges, performs a threshold operation and obtains ΔT. This operation is effective to the Gaussian noise jitter having a single peak. The sinusoidal jitter used in the jitter tolerance test has two peaks at both ends of the distribution. Therefore, ΔT cannot be obtained only by performing the simple threshold operation. Moreover, in the jitter tolerance measurement, the zero-crossings are caused to fluctuate by the timing jitter of 1 UIPP or more. As a result, the histogram has the distribution in which the probability density functions of adjacent edges overlap each other. From such a histogram, it is difficult to obtain ΔT. It is known that this histogram operation cannot secure a sufficient measurement precision unless about 10000 samples or more are obtained (T. J. Yamaguchi, M. Soma, D. Halter, J. Nissen, R. Raina, M. Ishida, and T. Watanabe, “Jitter Measurements of a PowerPC™ Microprocessor Using an Analytic Signal Method,” Proc. IEEE International Test Conference, Atlantic City, N.J., Oct. 3-5, 2000). Therefore, it is hard to reduce the measurement time. Moreover, K in the above equation does not have an ideal value. Therefore, by calibrating the instantaneous bit error rate with the actual bit error rate, the initial value for K has to be given. Also, a correction value ΔK has to be calculated from the difference between the long-term mean value of the instantaneous bit error rate and the actual bit error rate. Therefore, the conventional apparatus is poor in efficiency, requiring the longer test time.
Therefore, it is an object of the present invention to provide a measuring apparatus and a measuring method which are capable of overcoming the above drawbacks accompanying the conventional art. The above and other objects can be achieved by combinations described in the independent claims. The dependent claims define further advantageous and exemplary combinations of the present invention.
SUMMARY OF THE INVENTIONTo solve the foregoing problem, according to a first aspect of the present invention, there is provided a measuring apparatus for measuring reliability against jitter of an electronic device, including: a jitter tolerance estimator operable to estimate a jitter tolerance of a system including a transmission line and an electronic device based on the output signal output from the electronic device in response to an input signal input through a predetermined transmission line; a jitter tolerance degradation quantity estimator operable to estimate a quantity of jitter tolerance degradation which deteriorates by the deterministic jitter caused in the input signal by transmission through the transmission line based on the input signal, and a device jitter tolerance estimator operable to estimate a jitter tolerance of the electronic device by correcting the jitter tolerance of the system estimated by the jitter tolerance estimator based on the quantity of jitter tolerance degradation estimated by the jitter tolerance degradation quantity estimator.
The measuring apparatus may further include: a timing jitter estimator operable to estimate an output timing jitter sequence of the output signal based on the output signal; and a jitter transfer function measuring apparatus operable to measure the jitter transfer function in the electronic device based on the output timing jitter sequence, where the jitter tolerance estimator may estimate a jitter tolerance of the system based on a gain of the jitter transfer function.
The jitter tolerance estimator may estimate a jitter tolerance of the system further based on a phase of the jitter transfer function.
The measuring apparatus may further include: a timing jitter estimator operable to estimate an output timing jitter sequence of the output signal based on the output signal; and a jitter distortion estimator operable to estimate a jitter distortion of a timing jitter of the output signal based on the output timing jitter sequence, where the jitter tolerance estimator may estimate a jitter tolerance of the system based on the jitter distortion.
The jitter distortion estimator may estimate the jitter distortion based on a spectrum of a timing jitter of the output signal.
The timing jitter estimator may include: an instantaneous phase noise estimator operable to calculate an instantaneous phase noise of the output signal based on the output signal; and a resampler operable to generate the output timing jitter sequence obtained by resampling the instantaneous phase noise at predetermined timings.
The instantaneous phase noise estimator may include: an analytic signal transformer operable to transform the output signal to a complex analytic signal; an instantaneous phase estimator operable to estimate an instantaneous phase of the analytic signal based on the analytic signal; a linear instantaneous phase estimator operable to estimate a linear instantaneous phase of the output signal based on an instantaneous phase of the analytic signal; and a linear trend remover operable to calculate an instantaneous phase noise obtained by removing the linear instantaneous phase from the instantaneous phase based on the instantaneous phase and the linear instantaneous phase.
The timing jitter estimator may includes: a period jitter estimator operable to estimate a period jitter sequence of the output signal; an ideal edge timing estimator operable to estimate average period of the period jitter sequence; and an edge timing error estimation unit operable to estimate the output timing jitter sequence based on the average period of the period jitter sequence and the period jitter sequence.
The measuring apparatus may further include an input signal generating unit operable to generate the input signal to which a plurality of timing jitters are applied, wherein frequencies of the timing jitters are different from one another.
The measuring apparatus may further include a bit error rate estimator operable to detect a bit error rate of the output signal based on the output signal of the electronic device, wherein the input signal generating unit sequentially inputs the plurality of input signals on which the timing jitters are applied into the electronic device, wherein the amplitudes of the timing jitters are different from one another, and the jitter tolerance estimator estimates a peak-to-peak value of the timing jitter, in which the bit error rate estimator does not detect a bit error of the output signal, as the jitter tolerance.
The jitter tolerance estimator may receive the recovered clock signal output from the electronic device in response to the input signal as the output signal, and may estimate thee jitter tolerance of the system based on the recovered clock signal.
According to a second aspect of the present invention, there is provided a measuring apparatus for measuring reliability against jitter of an electronic device, including: a jitter tolerance estimator operable to estimate a jitter tolerance of an electronic device based on the output signal output from the electronic device according to the input signal input through the transmission line of which the transmission length is shorter than predetermined length, and does not cause a deterministic jitter; a jitter tolerance degradation quantity estimator operable to estimate a quantity of jitter tolerance degradation which deteriorates by the deterministic jitter caused in the input signal by transmission through a long transmission line when an input signal is input into the electronic device through the long transmission line longer than the transmission line and does cause a deterministic jitter; and a system jitter tolerance estimator operable to estimate the jitter tolerance of the system including a long transmission line and an electronic device based on the jitter tolerance of the electronic device and also based on the quantity of degradation of jitter tolerance.
The summary of the invention does not necessarily describe all necessary features of the present invention. The present invention may also be a sub-combination of the features described above.
The invention will now be described based on the preferred embodiments, which do not intend to limit the scope of the present invention, but exemplify the invention. All of the features and the combinations thereof described in the embodiment are not necessarily essential to the invention.
Moreover, the jitter transfer function estimator 103 has the jitter gain estimator 502 that estimates the gain of the jitter transfer function based on the output timing jitter sequence. In this example, the bit error rate estimator 102 calculates the bit error rate of the DUT based on the gain of the jitter transfer function. A method for calculating the gain of the jitter transfer function is described later.
The jitter gain estimator 502 estimates the gain of the jitter transfer function of the DUT based on a timing jitter in the input signal and a timing jitter in the output signal. The jitter gain estimator 502, for example, receives information indicative of the input timing jitter in the input signal, and the output timing jitter sequence calculated by the timing jitter estimator 501.
The jitter gain estimator 502 estimates the gain of the jitter transfer function of the DUT based on the received information indicative of the input timing jitter and the thus estimated output timing jitter sequence. In this case, the jitter gain estimator 502 calculates the output timing jitter value from the timing jitter sequence of the output signal. For example, the jitter gain estimator 502 calculates peak values or RMS values of the output timing jitter as the output timing jitter values based on the output timing jitter sequences. Alternatively, the jitter gain estimator 502 may receive the timing jitter sequence of the input signal and the timing jitter sequence of the output signal, and estimate gain of the jitter transfer function. In this case, the jitter gain estimator 502 may calculate the input timing jitter values from the input timing jitter sequences and may calculate the output timing jitter values from the output timing jitter sequences.
Then, in step of calculating a timing jitter value S222, the timing jitter value is calculated based on the timing jitter sequence. Step S222 may calculate the timing jitter values based on the output timing jitter sequences, or may calculate both the timing jitter values of the output signal and the timing jitter values of the input signal based on the input timing sequences and the output timing jitter sequences. For example, step S222 may calculate the root-mean-square value or the peak-to-peak value of the timing jitter sequence as the timing jitter value.
Then, in jitter transfer function estimation step S223, the jitter transfer function is calculated. Step S223 have the same or similar function as/to the jitter transfer function estimator 103 described referring to
The jitter phase difference estimator 503 calculates the phase difference between the input timing jitter and the output timing jitter based on the input timing jitter sequence and the output timing jitter sequence. That is, the jitter phase difference estimator 503 calculates the phase of the jitter transfer function. For example, the jitter phase difference estimator 503 calculates the phase of the jitter transfer function based on the following equation.
The bit error rate estimator 102 calculates the bit error rate of the DUT further based on the phase of the jitter transfer function. The method of calculating the bit error rate based on the phase of the jitter transfer function is described later.
In the measuring apparatus 100 using jitter transfer function measuring apparatus 101 of this example, the bit error rate estimator 102 calculates the bit error rate of the DUT based on the gain and phase of the jitter transfer function.
Moreover, in phase difference estimation step S2301, phase of the jitter transfer function is calculated based on the input timing jitter sequence and the output timing jitter sequence. Step S2301 calculates the phase of the jitter transfer function by using the same or similar method as/to the jitter phase difference estimator 503 described in
Moreover, in the jitter transfer function estimation step S223, either of the jitter gain estimation step S261 and the phase difference estimation step S2301 may be performed prior to the other, or may be performed simultaneously.
The jitter gain estimator 502 estimates the gain of the jitter transfer function. More specifically, input signals having different jitter amounts are supplied to the DUT one after another, and the jitter gain estimator 502 estimates the gain of the jitter transfer function based on the input timing jitter sequence of each input signal and the output timing jitter sequence corresponding to that input signal.
The jitter gain estimator 502 performs linear fitting for the relationship between a plurality of input timing jitter values and the output timing jitter values, as shown in FIG. 8, and then calculates a slope of the straight line as the gain of the jitter transfer function of the DUT, given a linear relationship between the two. In the following description, the jitter transfer function of the DUT is described.
When an input instantaneous phase noise of the input signal Δθ(nTs) and an output instantaneous phase noise of the output signal Δφ(nTs) are transformed into the frequency domain by Fourier transform, the following phase noise spectra is obtained.
where ƒJ is a jitter frequency (frequency offset from the clock frequency), and TS is a sampling period.
In a case where the sampling period TS is made equal to the clock period T of the clock recovery unit of the DUT and the instantaneous phase noises in the vicinity of the zero-crossings (rising edges or falling edges) are sampled, the input timing jitter Δθ[nT] and the output timing jitter Δφ[nT] are obtained. When Δθ[nT] and Δφ[nT] are transformed into the frequency domain by using Fourier transform, the following timing jitter spectra
are obtained. Since the timing jitter is wide-sense cyclostationary with a period T, the timing jitter spectra is more effective to analysis of a modulation noise source than phase noise spectra. However, when the timing jitter is made to pass through a narrow band-pass filter, the wide-sense cyclostationary signal can be transformed to a stationary signal,
ΔΘ(ƒJ)≈ΔΘ[ƒJ] (5)
ΔΦ(ƒJ)≈Δφ[ƒJ] (6)
are satisfied. That is, by using the narrow band-pass filter, sampling jitter signal at its zero-crossings (i.e., the time-dependent operation associated with the wide-sense cyclostationary signal) can be avoided.
The jitter transfer function of the DUT is defined as follows:
The jitter transfer function is given as a frequency response function of a constant-parameter linear system. The output timing jitter spectra of the clock recovery unit of the DUT is represented by using the jitter transfer function as follows:
ΔΦ[ƒJ]=HJ(ƒJ)ΔΘ[ƒJ] (10)
From the assumption of the linearity, a peak-to-peak value of the input timing jitter is also amplified by the gain of the jitter transfer function, so that the resultant value is given as a peak-to-peak value of the output timing jitter. Next, a method for measuring the gain of the jitter transfer function in frequency domain and time domain is discussed.
When |ΔΘ(ƒJ)| is not zero, the gains corresponding to the peak jitter and the RMS jitter can be estimated in frequency domain by the following equations, respectively.
Since the jitter transfer function is given as the frequency response function of the constant-parameter linear system, the jitter transfer function is not a function of the applied input amplitude. Based on this fact, the procedure in which the jitter transfer function is estimated in time domain is described. First, the peak-to-peak value of the input timing jitter is set in a segment in which the operation of the DUT is linear, and then the input/output relationship between Δθ[nT] and Δφ[nT] are measured for plural times. Thereafter, the input/output relationship between Δθ[nT] and Δφ[nT] shown in
Please note that the worst-case value in a certain time period corresponds to the peak-to-peak value (the peak value in frequency domain).
From the assumption of the linearity, a peak-to-peak value of the input jitter is amplified by the gain |Hj(ƒJ)| of the jitter transfer function, so as to provide a peak-to-peak value of the timing jitter of the recovered clock. The jitter transfer function can be estimated from a ratio of the peak values or mean values of the input and output jitters. Next, a method for measuring the gain of the jitter transfer function in frequency domain and time domain is discussed.
When |ΔΘ(ƒJ)| is not zero, the gain of the jitter transfer function can be estimated in frequency domain from the peak values or mean values of the timing jitter spectra (phase noise spectra) as follows:
Since the jitter transfer function is given as the frequency response function of the constant-parameter linear system, the jitter transfer function is not a function of the applied input amplitude to the system. Based on this fact, the procedure in which the jitter transfer function is estimated in time domain is described. First, the peak-to-peak value of the input timing jitter is set in a region in which the operation of the clock recovery device under test is a linear operation, and then the input/output relationship between Δθ[nT] and Δφ[nT] are measured for plural times. Thereafter, when the input/output relationship of the peak-to-peak jitter or the RMS jitter between Δθ[nT] and Δφ[nT] is subjected to linear fitting, as shown in
For example, in order to obtain the gain of the jitter transfer function by linear fitting, the measuring apparatus 100 may measure the input/output relationship between the input timing jitter sequence Δθ[nT] and the output timing jitter sequence Δφ[nT] about four times.
Referring to
Next, step of instantaneous phase estimation S802 estimates the instantaneous phase of the analytic signal. Step S802 performs the estimation in the similar manner to the instantaneous phase estimator 702 described referring to
Next, step of linear instantaneous phase estimator S803 estimates the linear component of the instantaneous phase of the signal received in step S801. Step S803 estimates the linear component of the instantaneous phase of the received signal in a similar manner to the linear phase estimator 703 described referring to
Next, linear trend removal step S804 removes the linear component from the instantaneous phase so as to calculate the instantaneous phase noise. Step S804 performs the calculation in a similar manner to the linear trend remover 704 described referring to
Next, Resampling step S1001 generates the timing jitter sequence obtained by sampling of the instantaneous phase noise. Step S1001 generates the timing jitter sequence in a similar manner to that of the resampler 901 described referring to
N is the number of samples of the timing jitter that were measured. On the other hand, the peak-to-peak timing jitter ΔφPP is the difference between the maximum value and the minimum value of Δφ[n] and is calculated by the jitter gain estimator 502 based on the following equation.
Next, the detection of the zero-crossings is described.
The jitter gain estimator 502 described referring to
The instantaneous phase Δθ[nT] of the bit clock is modulated by a sine wave cos (2πƒPMt). The data stream input to the DUT has the following timing jitter.
Δθ[nT]=Ki cos(2πƒPMt)|t=nT (21)
In this equation, 2Ki is the peak-to-peak value of the input jitter, while ƒPM is the phase modulation frequency. When the sinusoidal jitter that is sufficiently larger than the internal jitter generated by the DUT itself is applied to the DUT, the output timing of the recovered clock becomes
Δφ[nT]=Ki|HJ(ƒPM)|exp(−j<HJ(ƒPM))cos(2πƒPMt)|t=nT (22)
Where HJ(ƒPM) is the jitter transfer function of the DUT. The DUT has a clock recovery unit, and HJ(ƒPM) corresponds to the jitter transfer function of the clock recovery unit. From Equations (21) and (22), the peak-to-peak values of the sinusoidal jitter are bounded, namely,
ΔθPP<M1, ΔφPP<M2 (23)
The jitter frequency ƒJ is represented by the phase modulation frequency ƒPM.
ƒJ=ƒPM (24)
Thus, the worst-case value and the mean value of the peak jitter at the jitter frequency ƒJ are obtained as follows:
Moreover, the peak-to-peak jitter value and the RMS value in time domain are obtained as follows:
ΔφPP=max{(Worst[|ΔΦ[ƒJ]2])0.5 exp(j2πƒJk)}−min{(Worst[|ΔΦ[ƒJ]2])0.5 exp(j2πƒJk)} (27)
σΔφ=√{square root over (1/L{(mean[|ΔΦ[ƒJ]2])0.5 exp(j2πƒJk) }2)}{square root over (1/L{(mean[|ΔΦ[ƒJ]2])0.5 exp(j2πƒJk) }2)} (28)
In the above equations, |X|2 or (|X|2)0.5 can be calculated as |X|. From the above equations, when the sinusoidal jitter is applied to the input signal, the sinusoidal jitter provides deterministic jitter to the DUT. Moreover, the probability density function of the sinusoidal jitter corresponds to the worst case. The details of the sinusoidal jitter are described later.
Next, a bit error rate equation is derived considering the fluctuation of the rising edges of the input data stream due to the applied input jitter. When the timings tzero-crossing of the adjacent rising edges cross tdecision, respectively, the preceding bit or the next bit is discriminated at tdecision. That is, an erroneous decoding occurs. Since the probability of error for the preceding bit is equal to that for the next bit, the bit error rate is given as follows:
BER=ƒ(ΔalignPP)=½Pe(tdecision<tzero-crossing)+½Pe(tzero-crossing<tdecision) (29)
For simplification, tdecision is regarded as the optimum sampling instant and the timing fluctuation Δφ[nT] at this optimum sampling instant can be incorporated into the fluctuation of the input data stream, Δθ[nT]. It follows that only calculating the bit error rate caused by the alignment jitter is sufficient to get the desired estimates. Moreover, due to the symmetry of sinusoidal jitter distribution, Equation (29) can be re-written as:
BER=ƒ(ΔalignPP)=Pe(tdecision<tzero-crossing) (30)
Here, an alignment jitter is described. The alignment jitter is defined by P. R. Trischitta, and represents an alignment error between the timing jitter of the input signal and the timing jitter of the output signal (recovered clock). The alignment jitter is defined by the following equation.
Δalign[nT]=|(Δφ[nT]−Δθ[nT])| (31)
Δθ[nT] is the timing jitter of the input signal to the DUT and Δφ[nT] is the timing jitter of the output signal input.
From Equation (31), when the probability density function of the alignment jitter is obtained by substituting Equations (21) and (22) for terms in Equation (31), the following equation is obtained.
Δalign[nT]=|Ki{|HJ(ƒPM)|exp(−j<HJ(ƒPM))−1}cos(2πƒPMt)|t=nT (32)
When a certain value is given as the phase modulation frequency ƒPM, Ki{|HJ(ƒPM)exp(−j<Hj(ƒPM)−1)} becomes constant. Therefore, in the case of the sinusoidal jitter input, the probability density function of the alignment jitter follows a sinusoidal distribution.
Here, X=Ki{|HJ(ƒPM)|−1}. For simplification, the above sinusoidal distribution is approximated as a uniform distribution.
where X=ΔφP=ΔθP{|HJ(ƒPM)|−1}.
The sampling instant tdecision should be at the center of the bit time interval or as 0.5 UI (Unit Interval). Thus, the bit error rate becomes:
The bit error rate estimator 102 may calculate the bit error rate of the DUT based on Equation (36). In other words, based on the gain HJ(ƒPM) of the jitter transfer function of the DUT, the relationship between the input timing jitter and the bit error rate shown in
The measuring apparatus 100 may calculate a jitter tolerance of the DUT. Please note that the jitter tolerance means the threshold amount of the input timing jitter above which the erroneous bit decoding happens. For example, the jitter tolerance may be the minimum amount of the input timing jitter above which the bit error rate larger than zero occurs.
The bit error rate of the DUT can be calculated in accordance with Equation (36). The lower limit of the jitter tolerance is given from Equation (36) as follows:
Since |HJ(fPM)| is generally less than 1, the bit error rate and the jitter tolerance may be calculated by ||HJ(fPM)|−1|=1−|HJ(fPM)| in Equations (36) and (37).
The measuring apparatus 100 of this example calculates the bit error rate and the jitter tolerance based on the alignment errors of the input and output signals that are based on the gain of the jitter transfer function, as described associated with Equations (36) and (37). Since Equations (36) and (37) calculate the bit error rate and the jitter tolerance while considering the internal noise in the DUT to be zero, the bit error rate and the jitter tolerance represented by Equations (36) and (37) are the best-case values thereof. The measuring apparatus 100 may calculate the bit error rate and the jitter tolerance represented by Equations (36) and (37) as the best-case values of the bit error rate and jitter tolerance of the DUT or as the approximated values thereof.
The measuring apparatus 100 may calculate the bit error rate and jitter tolerance further based on the phase of the transfer function as described referring to
are obtained. The measuring apparatus 100 may calculate the bit error rate and jitter tolerance in accordance with Equations (38) and (39). Since the internal noise in the DUT is considered to be zero in Equations (38) and (39) as well as in Equations (36) and (37), the bit error rate and jitter tolerance represented by Equations (38) and (39) are also the best-case values of the bit error rate and jitter tolerance of the DUT. The measuring apparatus 100 may calculate the bit error rate and jitter tolerance represented by Equations (38) and (39) as the best-case values of the bit error rate and jitter tolerance of the DUT or as the approximated values thereof. Moreover, since
Re(|HJ(ƒPM)|exp(−j<HJ(ƒPM)))
is generally less than 1, the bit error rate and the jitter tolerance may be calculated by
∥HJ(ƒPM)|exp(−j<HJ(ƒPM))−1|=1−Re(|HJ(ƒPM)|exp(−j<HJ(ƒPM)))
in Equations (38) and (39).
Moreover, the measuring apparatus 100 may calculate the bit error rate and jitter tolerance of the DUT based on the following equations.
Where β is a correction constant which indicates performance degradation of the DUT, and is given in advance by measurement etc.
Moreover, the measuring apparatus 100 may calculate the bit error rate and jitter tolerance of the DUT further based on the internal noise in the DUT. In a case where the DUT includes a PLL for generating the recovered clock and the recovered clock is received as the output signal of the DUT, for example, the measuring apparatus 100 may calculate the bit error rate and the jitter tolerance of the DUT further based on the internal nose in the PLL.
The phase noise caused by the PLL internal noise is given as follows:
|1−HJ(ƒPM)exp(−j<HJ(ƒPM))|2|ΔΦ(ƒPM)|2 (ƒPM<ƒb) (40)
ƒb=ƒ0/2Q (41)
In the above, ƒb is the upper limit frequency of the band of the output signal of the DUT. For example, in a case where the DUT outputs the recovered clock as the output signal thereof, ƒb is the upper limit of the pass band of the PLL loop for generating that recovered clock. ƒb can be obtained from the clock frequency ƒ0 in accordance with Equation (41). Alternatively, fb can be obtained from the maximum value of the phase factor of the jitter transfer function.
When the term related to the phase noise in Equation (40) is added to the bit error rate represented by Equation (38), the following equation is obtained.
Therefore, the bit error rate and the lower limit of the jitter tolerance are obtained, respectively.
Note that, for ƒPM<ƒb, |HJ(ƒPM)|≈1.0. Thus, it is found that the lower limit of the jitter tolerance below ƒPM=ƒb is degraded to about ½ of the lower limit of the jitter tolerance above ƒPM=ƒb. Moreover, since
Re(|HJ(ƒPM)|exp(−j<HJ(ƒPM)))
is generally less than 1, the bit error rate and the jitter tolerance may be calculated by
∥HJ(ƒPM)|exp(−j<HJ(ƒPM))−1|=1−Re(|HJ(ƒPM)|exp(−j<HJ(ƒPM)))
in Equations (43) and (44).
The measuring apparatus 100 may calculate the bit error rate and jitter tolerance of the DUT in accordance with Equations (43) and (44). Since this calculation is further based on the internal noise in the DUT, the bit error rate and jitter tolerance of the DUT can be calculated more precisely.
As described above, the lower limit of the jitter tolerance can be obtained only from the jitter transfer function. For ƒPM<ƒb, the measurement of the jitter tolerance corresponds to a test of the effects of the phase noise. Since the jitter transfer function can be calculated simply by a computer, the bit error rate and the lower limit of the jitter tolerance can be calculated from Equations (36), (37), (38), (39), (43) and (44). Therefore, the bit error rate estimator 102 may calculate the bit error rate of the DUT in accordance with any of Equations (36), (38) and (43).
The wave form clipper 1701 removes the amplitude modulation components from the signal received by the timing jitter estimator 501. The waveform clipper 1701 replaces the signal value that is larger than a predetermined first threshold value with the first threshold value and also replaces the signal value that is smaller than a predetermined second threshold value with the second threshold value, so as to remove the amplitude modulation component of the signal. Moreover, the timing jitter estimator 501 described in the other examples may include the waveform clipper 1701 as in the present example. Since the waveform clipper 1701 removes the amplitude modulation components from the signal, the jitter transfer function can be calculated precisely.
Waveform clipping step S1801 removes the amplitude modulation components from the signal. Analytic signal transforming step S801 generates an analytic signal of the signal from which the amplitude modulation components have been removed. Step S1801 removes the amplitude modulation components in a similar manner to that of the waveform clipper 1701 described referring to
Low frequency component removal step S2001 removes the low frequency components from the signal. Step S2001 removes the low frequency components in a similar manner to that of the low frequency component remover 1901 described referring to
AD converter 9901 converts the analogue signal received by the timing jitter estimator 501 to a digital signal. AD converter 9901 supplies the digital signal to the analytic signal transformer 701, and the analytic signal transformer 701 generates the analytic signal based-on the digital signal. AD converter 9901 may use a high-speed AD converter, a digitizer, or a digital oscilloscope. Alternatively, the timing jitter estimator 501 described in the other examples may include the AD converter 9901 same as the timing jitter estimator 501 of this example.
AD conversion step S9801 converts the analogue signal to a digital signal. Analytic signal transforming step S801 generates the analytic signal of the converted digital signal. Step S9801 converts the analogue signal to the digital signal in a similar manner to that of the AD converter 9901 described referring to
The band-pass filter 1101 may be an analogue filter or a digital filter, or may be implemented by using digital signal processing such as FFT. Moreover, the band-pass filter 1101 may be construed so as to allow the bandwidth in which the components are allowed to pass to be varied freely. According to the analytic signal transformer 701 of this example, the analytic signal corresponding to the fundamental component of the received signal can be generated. Thus, the gain of the jitter transfer function can be calculated precisely. The generation of the analytic signal using the Hilbert transform is described below.
The analytic signal z(t) of the real signal x(t) is defined by the following complex signal.
z(t)≡x(t)+j{circumflex over (x)}(t) (45)
In the above equation, j is imaginary unit, and the imaginary part {circumflex over (x)}(t) of the complex signal z(t) is obtained by Hilbert transform of the real part x(t).
On the other hand, Hilbert transform of the time-domain waveform x(t) is defined by the following equation.
{circumflex over (x)}(t) is convolution of functions x(t) and (1/πt). In other words, Hilbert transform is equivalent to the output obtained by making x(t) pass through an all pass filter. Please note that the phase of the output {circumflex over (x)}(t) is shifted by π/2 although the magnitude of the components in the frequency domain is left unchanged.
The analytic signal and Hilbert transform are described in, for example, A. Papoulis, Probability, Random Variables, and Stochastic Processes, 2nd edition, McGraw-Hill Book Company, 1984.
The instantaneous phase φ(t) of the real signal x(t) is obtained from the analytic signal z(t) by using the following equation.
Next, algorithm for estimating the instantaneous phase using Hilbert transform is described. First, the signal to be measured shown in
is subjected to Hilbert transform so as to obtain a signal corresponding to the imaginary part of the complex signal
thereby the signal under test x(t) is transformed to the analytic signal,
shown in
The obtained analytic signal has been subjected to the band-pass filtering by the band-pass filter 1101. Therefore, the jitter corresponding to the fluctuation of the fundamental frequency of the signal to be measured can be calculated precisely.
Then, the instantaneous phase estimator 702 estimates the phase function φ(t) shown in
φ(t) represents the principal value of the phase, and has discontinuous points −π and π. Finally, by unwrapping the discontinuous phase function φ(t) (that is, appropriately adding integral multiples of 2π to the principal value φ(t)), the discontinuities can be removed, so that the instantaneous phase φ(t) shown in
The analytic signal transformer 701 may compensate the real part for delay time τ, as represented by the following equation.
z(t)=x(t−τ)+j{circumflex over (x)}(t) (53)
As represented by Equation (53), the high accuracy analytic signal can be obtained in a case where the delay time τ corresponding to the filter delay is observed in the Hilbert transforming procedure by the analytic signal transformer 701 generating the analytic signal. Moreover, the timing jitter estimator 501 may calculate the instantaneous phase φ(t) after the linear phase term has been removed, in accordance with the following equation.
Moreover, the timing jitter estimator 501 may calculate the instantaneous phase φ(t) after compensating the delay time τ caused by the Hilbert transform, in accordance with the following equation.
Please note that ƒJ represents the jitter frequency of the signal x(t). By removing the linear phase term, the instantaneous phase noise of the signal x(t), shown in
Then, in Hilbert transforming step S1202, the band-limited signal is subjected to Hilbert transform so as to generate a Hilbert pair. Step S1202 performs the generation of the Hilbert pair in a similar manner to that of the Hilbert transformer 1102 described referring to
Then, in output step S1203, the band-limited signal is output as the real part of the analytic signal, and the band-limited signal after being subjected to Hilbert transform is output as the imaginary part of the analytic signal.
Then, in negative frequency component removal step S1402, negative frequency components in the two-sided spectra in frequency domain are removed. Step S1402 may have a similar function to that of the bandwidth limiter 1302 described referring to
Then, in bandwidth limiting step S1403, the frequency components in the vicinity of the positive fundamental frequency in the transformed signal in frequency domain are extracted. Step S1403 may have a similar function to that of the bandwidth limiter 1302 described referring to
The signal in frequency domain is then transformed to a signal in time domain in step S1404. Step S1404 may generate the signal in time domain in a similar manner to that of the frequency-domain to time-domain transformer 1303 described referring to
In the analytic signal transformer 701 described referring to
In the case where the signal components of the signal x(t) were multiplied by the window function, the signal x(t) is subjected to amplitude modulation. According to the analytic signal transformer 701 of this example, however, the amplitude modulation of the signal x(t) can be corrected by performing multiplication by a reciprocal of the window function in the amplitude corrector 1507.
The window function multiplier 1503 outputs the signal x(t) w(t) obtained by multiplying the signal x(t) by the window function w(t) to the time-domain to frequency-domain transformer 1504. The time-domain to frequency-domain transformer 1504 transforms the received signal to a signal in frequency domain. The bandwidth limiter 1505 outputs the spectra Z(f) obtained by replacing the negative frequency components of that signal with zeros.
The frequency-domain to time-domain transformer 1506 outputs a signal IFFT [Z(f)] obtained by transforming the spectra Z(f) to a signal in time domain. In this example, the analytic signal transformer 701 may output the real part and the imaginary part of the signal output from the frequency-domain to time-domain transformer 1506 as the real part and the imaginary part of the analytic signal. The real part xreal(t) and the imaginary part ximag(t) of the analytic signal are the real part Re{IFFT[Z(f)]} and the imaginary part Im{IFFT[Z (f)]} of the output signal from the frequency-domain to time-domain transformer 1506, respectively.
w′(t)xreal(t)=Re{IFFT[Z(ƒ)]}
w′(t)ximag(t)=Im{IFFT[Z(ƒ)]} (56)
w′ (t) represents the transformed window function w(t) from the spectra Z(f). The real part xreal(t) and the imaginary part ximag(t) of the analytic signal are influenced by the amplitude modulation by the window function w(t) to approximately the same degree. Therefore, the instantaneous phase represented by Equation (54) is represented by the following equation.
In a case of calculating the instantaneous phase of the signal x(t) in this example, as represented by Equation (57), the phase estimation errors caused by the amplitude modulation by the window function can be cancelled in the real part and the imaginary part. On the other hand, if the amplitude modulation by the window function occurs, it results in the phase estimation error as given by the following equation.
Since the phase estimation errors associated with xreal(t) and ximag(t) can be cancelled with each other in this example, it is possible to calculate the instantaneous phase with no phase estimation error caused by the amplitude modulation by the window function. In other words, as is apparent from Equations (56) and (57), in a case that the real part Re{IFFT[Z(f)]} and the imaginary part Im{IFFT[Z(f)]} of the output signal of the frequency-domain to time-domain transformer 1506 are output as the real part and the imaginary part of the analytic signal, the instantaneous phase estimator 702 can calculate the instantaneous phase of the signal x(t) precisely.
Moreover, as shown in
The time-domain to frequency-domain transformer 1504, the bandwidth limiter 1505 and the frequency-domain to time-domain transformer 1506 have the same or similar functions and structures as/to those of the time-domain to frequency-domain transformer 1301, the bandwidth limiter 1302 and the frequency-domain to time-domain transformer 1303 described referring to
Next, the operation of the analytic signal transformer 701 of the present invention is described. First, the buffer memory 1501 stores the signal to be measured. The waveform data selector 1502 then extracts waveform section of the signal stored in the buffer memory 1501. The window function multiplier 1503 then multiplies the waveform section selected by the waveform data selector 1502 by the window function. Then, the time-domain to frequency-domain transformer 1504 performs FFT operation on the waveform section multiplied by the window function, so that the signal in time domain is transformed to the two-sided spectra in frequency domain. Next, the bandwidth limiter 1505 replaces the negative frequency components of the two-sided spectra in frequency domain with zeros, so as to obtain one-sided spectra. The bandwidth limiter 1505 then replaces the frequency components of the one-sided spectra other than those around the fundamental frequency of the signal to be measured with zeros so as to leave the frequency components around the fundamental frequency of the signal to be measured only, thereby the bandwidth of the signal in frequency domain is limited. Then, the frequency-domain to time-domain transformer 1506 performs inverse FFT on the band limited one-sided spectra, so that the signal in frequency domain is transformed to a signal in time domain. The amplitude corrector 1507 multiplies the signal in time domain by the reciprocal of the window function so as to generate the band limited analytic signal. The analytic signal transformer 701 then checks whether or not the buffer memory 1501 stores the waveform data that has not been processed. If the unprocessed waveform data is determined to be left in the buffer memory 1501, the waveform data selector 1502 selects the next waveform section. After the waveform data selector 1502 extracts the waveform section so that it partially overlaps the previously extracted waveform section, the analytic signal transformer 701 repeats the aforementioned operations.
Then, waveform data selection step S1602 selects a part of the signal to be measured, that was stored in buffer memory step S1601, and extracts the selected waveform section as the waveform data. Step S1602 has the same or similar as/to that of the waveform data selector 1502 described referring to
Then, in window function multiplying step 1603, the waveform data extracted in step S1602 is multiplied by a predetermined window function such as Hanning function. Step S1603 has the same or similar function as/to that of the window function multiplier 1503 described referring to
Then, in time-domain to frequency-domain transforming step S1604, the waveform data multiplied by the window function is transformed to a signal in frequency domain. Step S1604 has the same or similar function as/to that of the time-domain to frequency-domain transformer 1504 described referring to
Then, in negative frequency component removal step S1605, the negative frequency components of the signal transformed into frequency domain are removed. Step S1605 has the same or similar function as/to that of the bandwidth limiter 1505 described referring to
Then, in bandwidth limiting step S1606, the frequency components of the signal transformed into frequency domain in the vicinity of the fundamental frequency thereof are extracted. Step S1606 has the same or similar function as/to that of the bandwidth limiter 1505 described referring to
Then, in frequency-domain to time-domain transforming step S1607, the signal having the limited bandwidth is transformed to a signal in time domain. Step S1607 has the same or similar function as/to that of the frequency-domain to time-domain transformer 1506 described referring to
Then, in amplitude correction step S1608, the amplitude modulation components of the signal transformed into time domain are removed. Step S1608 has the same or similar function as/to that of the amplitude corrector 1507 described referring to
Next, in decision step S1609, it is determined whether or not there is any unprocessed data of the signal to be measured that was stored in step S1601. If the unprocessed data is left, waveform data selection step S1601 extracts the next part of the signal in such a manner that it partially overlaps the previously extracted part. Step S1610 has a similar function to step S1602. When it is determined in step S1609 that there is no unprocessed waveform data, the procedure is finished.
Next, a method of estimating the phase of the jitter transfer function is described below.
The jitter phase difference estimator 503 estimates the timing jitter spectra of the input signal by using Equation (3) in step S2604, which estimates the timing jitter spectra from the input timing jitter. Moreover, the jitter phase difference estimator 503 estimates the timing jitter spectra of the output signal by using Equation (4) in step S2605, which estimates the timing jitter spectra from the output timing jitter. Moreover, the jitter phase difference estimator 503 estimates the phase difference between the input and output timing jitters by using Equation (9) in step S2606, which estimates differences between the input and output timing jitter from the timing jitter spectra. Furthermore, jitter phase difference estimator 503 may estimate the phase difference between the input and output timing jitter by calculating the arctangent of the ratio of imaginary part to real part of the jitter transfer function (i.e. Im/Re) in step S2606.
The phase difference between the input and output timing jitters may be calculated by calculating the timing difference between the zero-cross timing of the input instantaneous phase noise waveform and that of the output instantaneous phase noise, calculating a ratio of the calculated timing difference to the period of the applied jitter (reciprocal of the jitter frequency) and multiplying the calculated ratio by 2π (rad) (or 360 degrees). Similarly, it may be calculated by calculating the timing difference between the zero-cross timing of the input timing jitter waveform and that of the output timing jitter waveform, calculating the ratio of the calculated timing difference to the period of the applied jitter (the reciprocal of the jitter frequency) and multiplying the calculated ratio by 2π (rad) (or 360 degrees).
Moreover, the phase of the jitter transfer function may be calculated by the instantaneous phase noise waveform of the input and output signal.
In step S2504, where the phase noise spectra is obtained from the input instantaneous phase noise, the jitter phase difference estimator 503 estimates the phase noise spectra of the input signal by using Equation (1). Moreover, the jitter phase difference estimator 503 estimates the phase noise spectra of the output signal by using Equation (2) in step S2505 where the phase noise spectra is obtained from the output instantaneous phase noise. Furthermore, the jitter phase difference estimator 503 obtains the phase difference between the input and output instantaneous phase noises by using Equation (9) in step S2506, where phase difference between the instantaneous phase noises is obtained from the phase noise spectra, and estimates phase of the jitter transfer function.
The signal input means 301 supplies a signal obtained by applying a desired jitter to the input signal to be input to the DUT. The signal input means 301 applies sinusoidal jitter to the input signal, for example. By applying the sinusoidal jitter, the bit error rate can be calculated precisely. The details in the case of applying the sinusoidal jitter are described later.
The jitter tolerance estimator 302 estimates a jitter tolerance of the DUT based on the jitter transfer function of the DUT. The jitter tolerance estimator 302 may estimate the jitter tolerance based on the gain of the jitter transfer function as described above. Moreover, the jitter tolerance estimator 302 may estimate the jitter tolerance further based on the phase of the jitter transfer function. Moreover, the jitter tolerance estimator 302 may estimate the jitter tolerance further based on the internal noise of the DUT.
The jitter tolerance estimator 302 may calculate the jitter tolerance of the DUT in accordance with Equation (37), (39) or (44). Moreover, the jitter tolerance estimator 302 may calculate the best-case value of the jitter tolerance of the DUT as described above.
The jitter transfer function measuring apparatus 101 estimates the jitter transfer function of the DUT based on the input timing jitter that the signal input means 301 applies to the input signal and the output timing jitter in the output signal of the DUT. The signal input means 301 applies input timing jitters having different jitter amplitude to the input signal one after another. In this example, the jitter transfer function measuring apparatus 101 receives the signal input to the DUT and the signal output from the DUT.
Next, the jitter transfer function is calculated in step S201. Step S201 is the similar step to jitter transfer function estimation step S201 in
Next, the jitter tolerance of the DUT is calculated in jitter tolerance estimation step S402. Step S402 has the same or similar function as/to the jitter tolerance estimator 302 described referring to
The clock recovery unit 2101 generates a recovered clock signal of the output signal based on the output signal of the DUT. The jitter transfer function measuring apparatus 101 receives the recovered clock as the output signal from the DUT and calculates the jitter transfer function of the DUT based on the recovered clock signal.
Then, in jitter transfer function estimation step S201, the jitter transfer function of the DUT is calculated. Step S201 has the same or similar function as/to that of the jitter transfer function measuring apparatus 101 described referring to FIG. 45, and may be performed by using the jitter transfer function measuring apparatus 101.
Then, in bit error rate estimation step S202, the bit error rate of the DUT is calculated. Step S202 has the same or similar function as/to that of the bit error rate estimator 102 described referring to
The clock recovery unit 3003 receives the input signal (serial bit stream) and generates the recovered clock for outputting the output signal based on the input signal (serial bit stream) received. In the present example, the clock recovery unit 3003 has a phase-locked-loop (PLL).
The flip-flop 3001 supplies the input signal to the serial-parallel converter 3002. The serial-parallel converter 3002 receives the recovered clock and converts the serial input signal to the parallel output signal based on the timings of the recovered clock.
The measuring apparatus 100 receives the recovered clock generated by the clock recovery unit 3003 as the output signal of the DUT, and then calculates the bit error rate and/or jitter tolerance of the DUT based on the recovered clock.
The timing estimator 3100 estimates a timing error sequence of the input signal for testing the DUT and a timing error sequence of the output signal that the DUT outputs in response to the input signal. The timing difference estimator 3102 calculates the timing differences between the timing error sequence of the input signal and that of the output signal. The timing difference estimator 3102 may calculate the timing differences based on the peak values or the RMS values of the input timing error sequences and the output timing error sequences. The bit error rate estimator 102 estimates the bit error rate of the DUT based on the thus calculated timing differences. Equations indicating the relationship between the timing differences and the bit error rate may be given in advance to the bit error rate estimator 102. Also, Tables indicating the relationship between the timing differences and the bit error rate may be given in advance to the bit error rate estimator 102.
Then, in timing difference estimation step S3202, the timing differences between the input and output signals are calculated. Step S3202 has the same or similar function as/to that of the timing difference estimator 3102 described referring to
Then, in bit error rate estimation step S3203, the bit error rate of the DUT is calculated. Step S3203 has the same or similar function as/to that of the bit error rate estimator 102 described referring to
The resampler 3304 may supply the timing n of the timing error sequences Δφ[nT] to the ideal timing estimator 3301. Moreover, the resampler 3304 may sample the instantaneous phase at the zero-crossing timing of the waveform of the real part of the analytic signal. Furthermore, the resampler 3304 may supply the sampling timing in the resampler 3304 to the ideal timing estimator 3301 as the timing n. The ideal timing estimator 3301 calculates the ideal timings of the input and output signal based on the timing n supplied by the resampler 3304.
The analytic signal transformer 701, the instantaneous phase estimator 702, and the resampler 3304 have the same or similar functions and structures as/to the analytic signal transformer 701, the instantaneous phase estimator 702, and the resampler 901 shown in
The ideal timing estimator 3301 calculates the initial phase angles and average frequencies of the linear instantaneous phase of the input and output signals, that is shown in
Then, in resampling step S3402, the input and output timing jitter sequences are generated by sampling the instantaneous phase noise of the input and output signal. Step S3402 has the same or similar function as/to that of the resampler 3304 described referring to
Then, in ideal timing estimation step S3403, the initial phase angles and average frequencies of the input and output signals are calculated, and the ideal timings of the input and output signals are also calculated. Step S3403 has the same or similar function as/to that of the ideal timing estimator 3301 described referring to
Then, in timing error calculation step S3406, the timing sequences of the input and output signals are generated. Step S3406 has the same or similar function as/to the timing error calculator 3305 described referring to
Next, the alignment jitter is described. An alignment jitter is defined by P. R. Trischitta, and represents the alignment error between the timing jitter of the input signal and the timing jitter of the output signal (recovered clock). The alignment jitter is defined by the following equation.
Δalign[nT]=|(Δφ[nT]−Δθ[nT])| (31)
Δθ[nT] and Δφ[nT] are the timing jitter sequence of the input signal to the DUT and that of the output signal of the DUT, respectively. The peak-to-peak value and the RMS value of the alignment jitter are represented as follows:
ΔalignPP=|(Δφ−Δθ)PP| (58)
σΔalign=√{square root over (σΔφ2+σΔθ2−2ρσΔφσΔθ)} (59)
ρ is a correlation coefficient between the timing jitter of the recovered clock and the timing jitter of the data input to the DUT. For example, it is assumed that the timing jitter of the recovered clock is strongly correlated with the timing jitter of the input data of the DUT. In this case, ρ can be considered to be 1.0, and the following relationship is established.
σΔalign≈√{square root over ((σΔφ−σΔθ)2)}=|σΔφ−σΔθ|
Thus, the alignment error between the input data and the recovered clock can be minimized. At this time, the clock recovery unit has the minimum bit error rate. On the other hand, when the timing jitter of the recovered clock is completely uncorrelated with the timing jitter of the input data of the clock recovery unit, ρ can be considered to be 0.0, and the following relationship is satisfied.
σΔalign=√{square root over (σΔφ2+σΔθ2)}
Because of the alignment error between the input data and the recovered clock, this DUT has the bit error rate that is not neglectable. Moreover, the peak-to-peak value of the timing jitter of the recovered clock is given as follows:
ΔφPP=ΔθPP√{square root over (max[|HJ(ƒJ)|2])} (60)
The peak-to-peak value of the alignment jitter is obtained as follows:
ΔalignPP=ΔθPP{|√{square root over (max[|HJ(ƒJ)|2])}−1|} (61)
Next, the case where the sinusoidal jitter is applied to the input signal to the DUT is described. An input data signal x(t) is phase modulated with the timing jitter Δθ[nT]. The recovered clock signal y(t) is also phase modulated with the timing jitter Δφ[nT].
x(t)=A sin(2πƒbt+Δθ[t]) (62)
y(t)=B sin(2πƒbt+Δφ[t]) (63)
In the above equations, ƒb is a bit rate (bit clock frequency). When the instantaneous phase noises of the bit clock Δθ[nT] and Δφ[nT] are made to correspond to the sine wave cos(2πƒPMt), the sinusoidal jitter is obtained. On the other hand, when the sinusoidal jitter is demodulated, the sine wave is obtained. Since this sine wave corresponds to a line spectrum in frequency domain, the jitter frequency ƒJ is given by a single frequency ƒPM. Therefore, a ratio of the demodulated sine wave at the frequency of ƒPM provides the jitter transfer function expressed by Equation (8).
On the other hand, when Δθ[nT] and Δφ[nT] are adapted to correspond to Gaussian noise ng(t), the Gaussian noise jitter is obtained. When the Gaussian noise jitter is demodulated, the Gaussian noise wave is obtained. Since the Gaussian noise corresponds to wide band spectrum in frequency domain, the jitter frequency ƒJ is given by a frequency band (Flower, Fupper). Therefore, the ratio of the input and output spectrum in this frequency band gives the jitter transfer function.
It is known that, when the truncated Gaussian distribution jitter and the sinusoidal jitter are compared to each other at the same peak-to-peak value, the sinusoidal jitter results in the bit error rate with penalty of about 1 dB larger than that of the Gaussian distribution. In other words, the sinusoidal jitter can provide the worst-case jitter distribution to the DUT. Therefore, in the case where the measuring apparatus 100 applies the sinusoidal jitter to the input signal, the test of the bit error rate and jitter tolerance can be performed precisely.
Next, the jitter tolerance is described. The measurement of the jitter tolerance is extension of the bit error test. More specifically, the timing jitter Δθ[nT] of the input data to the DUT is made to fluctuate by the sinusoidal jitter or the like, thereby testing the bit error rate. While the jitter frequency ƒJ is fixed and the applied jitter amount is increased, the minimum applied jitter amount that causes the occurrence of the bit error rate is obtained. Next, the relationship between the sinusoidal jitter and the bit error rate is described. First, a decision boundary or sampling instant is described. In the description of the decision boundary, it is assumed that the bit stream has no timing jitter.
Let consider a test time required for the bit error rate test. For example, the application of a pseudo-random binary sequence having a pattern length of 215-1 that is phase-modulated with the jitter frequency of 5 MHz in order to perform the jitter tolerance test for a 2.5 Gbps serial communication device requires only 13 μsec. Moreover, the application of a pseudo-random binary sequence having a pattern length of 223-1 requires only 3.4 msec. On the other hand, the test for the bit error rate of 10−9 requires 0.4 sec. Thus, this test time is independent of the pattern length. Moreover, in order to test the bit error rate of 10−12, 400 sec is required. Moreover, when the applied jitter amount is increased, the PLL circuit in the DUT may not work correctly. In particular, as the bit clock frequency increases, this type of bit error may occur in a case that the applied jitter amount is slightly increased. From the above, according to the method in which the occurrence of the bit error is detected, it is hard to obtain a measurement having good repeatability or to shorten the test time. Therefore, it is necessary to find a method which does not require direct detection of the bit error occurrence to shorten the test time.
The measuring apparatus 100 described referring to
In other words, the measuring apparatus 100 may include the bit error rate estimator that estimates the bit error rate of the DUT based on the jitter transfer function of the DUT given in advance. Moreover, the measuring apparatus 100 may include the jitter tolerance estimator that estimates the jitter tolerance of the DUT based on the gain of the jitter transfer function of the DUT given in advance. In this case, the bit error rate estimator and jitter tolerance estimator may have the same or similar functions and structures as/to the bit error rare estimator 102 and the jitter tolerance estimator 302 mentioned above.
The measuring apparatus 100 described referring to
The jitter transfer function measuring apparatus 101 measures the jitter transfer function between the received input signal and the received output signal. Operation of the jitter transfer function measuring apparatus 101 is the same as the operation of the jitter transfer function measuring apparatus 101 described referring to
Moreover, the signal input means 301 generates the input data signal supplied to the DUT 3000, and includes a pattern generator 4012, a timing generator 4014, and a serializer 4010. The pattern generator 4012 supplies pattern data for generating the input data signal to the serializer 4010, and the timing generator 4014 supplies the input data clock signal for generating the input signal to the serializer 4010. The serializer 4010 generates the input data signal based on the received pattern data and the received input data clock. For example, the serializer 4010 outputs each data of the received pattern data one after another in response to a timing of edges of the received input data clock signal.
Moreover, as explained in.
As the output signal, when the recovered clock signal is selected, the jitter transfer function measuring apparatus 101 can measure the jitter transfer function in the clock recovery unit 3003 described referring to
Moreover, as the output signal, when the output data signal is selected, the jitter transfer function measuring apparatus 101 can measure the jitter transfer function in all the structure of the DUT 3000 described referring to
Moreover, also in the measuring method described referring to
Moreover, the pattern generator 4012 may generate pattern data as shown in Data C, in which 1 and 0 is repeated for every bit number same number as the output pins. Also in this case, the jitter transfer function can be measured more precisely same as the Data B, and the pattern data can be generated easily.
The signal capturing unit 4062 captures the output signal of the DUT. Moreover, the signal capturing unit 4062 measures a period of the captured output signal etc.
The period jitter estimator 4004 estimates a period jitter sequence of the output signal based on the measurement result in the signal capturing unit 4062. Here, the period jitter sequence may indicate length of each cycle of the output signal, and may indicate timing of each edge of the output signal.
The ideal edge timing estimator 4006 estimates an average period of the output signal based on the period jitter sequence. For example, when the period jitter sequence indicates the length of each cycle of the output signal, the ideal edge timing estimator 4006 estimates an average of each value of the period jitter sequence as an average period of the output signal.
Next, the edge timing error estimator 4008 estimates the output timing jitter sequence based on the average period of the period jitter sequence, and the period jitter sequence. For example, the output timing jitter may be estimated by calculating an ideal edge timing sequence indicating ideal timing of each edge of the output signal, and calculating difference between the ideal edge timing sequence and the period jitter sequence indicating timing of each edge of the output signal, based on the average period of the output signal.
The timing jitter sequence of the output signal can be estimated by the structure of the timing jitter estimator 501 in this example as well as the timing jitter estimators 501 of the other examples. Moreover, the timing jitter sequence of the input signal of the DUT may be estimated.
First, the signal, from which the timing jitter is to be estimated, is captured in signal capturing step S8000. The step S8000 may be performed by using the signal capturing unit 4062 described referring to
Next, the period jitter sequence of the captured signal is estimated in a period jitter sequence estimation step S8002. The step S8002 may be performed by using the period jitter estimator 4004 described referring to
Next, the average period of the signal is estimated in ideal edge timing estimation step S8004. The step S8004 may be performed by using the ideal edge timing estimator 4006 described referring to
Next, the timing jitter sequence of the signal is estimated in the edge error estimation step S8006. The step S8006 may be performed by using the edge timing error estimator 4008 described referring to
In
Moreover, the measuring apparatus 100 may measure the jitter tolerance using Equation (39.2). The more accurate jitter tolerance can be measured by substituting, for example, 0.75 for 8 in this case.
The measuring apparatus 100 includes a signal input means 301, a timing jitter estimator 501, a jitter distortion estimator 4100, and a jitter related transmission penalty estimator 4102. The signal input means 301 has the same function and the same structure as the signal input means 301 described referring to
The jitter distortion estimator 4100 estimates the jitter distortion of the output timing jitter sequence. Here, the jitter distortion of the output timing jitter sequence is distortion of the output timing jitter of the output signal which the DUT 3000 actually outputs in response to the input signal, against the ideal timing jitter of the output signal which the DUT 3000 is to output in response to the input signal.
The jitter related transmission penalty estimator 4102 estimates reliability of the DUT 3000 against jitter based on the jitter distortion. For example, the jitter related transmission penalty estimator 4102 estimates the jitter tolerance of the DUT 3000. Moreover, the jitter related transmission penalty estimator 4102 may estimate whether the DUT 3000 operates normally in response to the input timing jitter of a predetermined amplitude. That is, the signal input means 301 may apply the input timing jitter of desired amplitude to the input signal, and may supply it to the DUT 3000, and the jitter related transmission penalty estimator 4102 may estimate the reliability of the DUT 3000 against jitter for the amplitude of the input timing jitter.
Next, in a jitter amplitude setting step S4502, amplitude of the input timing jitter, applied to the input signal to the DUT 3000, is set up. The steps S4500 and S4502 may be performed using the signal input means 301 described referring to
Next, in a timing jitter sequence measurement step S4504, the output timing jitter sequence is measured based on the output signal of the DUT 3000. The step S4504 may be performed using the timing jitter estimator 501 described referring to
Next, in a jitter distortion measurement step S4506, the jitter distortion of the timing jitter of the output signal, which DUT 3000 actually outputs, against the timing jitter of the output signal which DUT 3000 is to output in response to the input signal, is measured. The step S4506 may be performed using the jitter distortion estimator 4100 described referring to
Next, in a judging step S4508, it is judged whether the jitter distortion is larger than a predetermined value. The step S4508 may be performed using the jitter related transmission penalty estimator 4102 described referring to
In the step S4508, if the jitter distortion is smaller than the predetermined value, the sequence returns to the step S4502 again, where the input signal, to which input timing jitter of larger amplitude than the previous time is applied, inputs to the DUT 3000, and the processing of the steps S4502-S4508 is repeated until the jitter distortion in the step 4508 becomes larger than the predetermined value.
If the jitter distortion is larger than the predetermined value in the step S4508, the jitter tolerance of the DUT 3000 is estimated in the jitter tolerance estimation step S4510. In the step S4510, the amplitude of the input timing jitter may be estimated as a jitter tolerance of the DUT 3000 at the frequency of the input timing jitter, when being judged in the step S4508 that the jitter distortion is larger than the predetermined value. Moreover, the step S4510 may be performed using the jitter related transmission penalty estimator 4102 described referring to
Next, in a step S4512, it is judged whether there is any input timing jitter of another frequency which is to be measured further. If there is another input timing jitter frequency (or frequencies) which is to be measured, the frequency is set up in the S4500 and the processing of the steps S4500-S4510 is repeated. Moreover, if there is no input timing jitter frequency (or frequencies) to be measured any more, the measurement of the jitter tolerance is ended. That is, the signal input means 301 supplies the input signal, to which a plurality of sinusoidal jitters having different frequency are applied, to the DUT 3000 for example, and the jitter related transmission penalty estimator 4102 estimates the reliability of the DUT against the jitter for every frequency of the sinusoidal jitters. Moreover, the signal input means 301 may supply the input signal, to which the input timing jitters having a plurality of frequency components is applied, to the DUT 3000. In this case, the reliability of the DUT 3000 against the jitters is measured for every frequency components.
As described referring to
That is, as shown in the circles of
As described referring to
The timing jitter spectrum estimator 4104 receives the output timing jitter sequence, and estimates the jitter spectrum of the output timing jitter sequence. For example, the timing jitter spectrum estimator 4104 estimates the jitter spectrum with Fourier transformation.
The jitter distortion calculator 4106 calculates the jitter distortion of the output timing jitter based on the jitter spectrum.
For example, the jitter distortion calculator 4106 calculates the distortion of the jitter spectrum of the output timing jitter in the output signal output from the DUT 3000, against the jitter spectrum of the output timing jitter in the output signal which is to be output from the DUT 3000.
For example, when the sinusoidal jitter having a predetermined frequency is applied to the input signal, the spectrum of the output timing jitter has a peak at the fundamental frequency of the sinusoidal jitter, and having the magnitude according to the jitter transfer function.
When the amplitude of the applied input sinusoidal jitter is in the linear response region described referring to
According to the jitter distortion estimator 4100 in this example, it can be judged that whether a bit error occurs in the output signal of the DUT 3000 by the applied input timing jitter. Moreover, the jitter tolerance of the DUT 3000 can be estimated by performing the same estimation for a plurality of input timing jitters having different amplitude.
When the amplitude of the sinusoidal jitter, which is applied to the input signal, is in the nonlinear response region described referring to
In this example, the jitter distortion estimator 4100 generates the jitter histogram of the output timing jitter sequence, and estimates the jitter distortion of the output timing jitter based on the jitter histogram. For example, the jitter distortion estimator 4100 may estimate the distortion of the output timing jitter against the input sinusoidal jitter based on whether there are two peaks at the both ends of a jitter histogram.
First, the measuring apparatus 100 in this example measures the jitter tolerance by the method described referring to
The jitter distortion estimator 4100 estimates the jitter distortion of the output timing jitter of the output signal output from the DUT 3000 in response to the first test signal, against the ideal timing jitter of the output signal which the DUT 3000 is to output in response to the first test signal.
Then, the jitter related transmission penalty estimator 4102, which is an example of the judging unit judges whether the jitter tolerance estimated by the jitter tolerance estimator 302 is the right value based on the jitter distortion estimated by the jitter distortion estimator 4100.
When the jitter related transmission penalty estimator 4102 judges that the jitter tolerance is not the right value, the signal input means 301 supplies a second test signal to the DUT 3000, where the timing jitter having smaller jitter amplitude than the first test signal is applied on the second test signal, and the jitter distortion estimator 4100 estimates the jitter distortion of the output timing jitter of the output signal which DUT 3000 outputs in response to the second test signal, against the ideal timing jitter of the output signal which DUT 3000 is to output in response to the second test signal. And the jitter related transmission penalty estimator 4102 newly estimates the jitter tolerance based on the jitter distortion corresponding to the second test signal estimated by the jitter distortion estimator 4100. For example, the jitter tolerance may be estimated newly by the processing of the steps of S4502-S4508 described referring to
According to the measuring apparatus 100 in this example, the jitter tolerance of the DUT 3000 can be measured precisely and rapidly. That is, since the jitter tolerance is measured by each method described referring to
Here, the deterministic jitter means timing variation in delay of each edge of the input signal which deviates according to the signal pattern of the input signal. That is, the deterministic jitter means the variation in delay time of the edges caused by, for example, a time interval between the edges of the input signal.
Since the transmission line includes an inductance component, a capacitance component, etc., a difference occurs in rising or falling time of each edge by the edge interval of the input signal. Therefore, the jitter (deterministic jitter) occurs at the timing of the rising edge or the timing of the falling edge of the input signal with respect to the ideal edge timing. The deterministic jitter is defined by the pattern of the input signal, the property of the transmission line per unit length, and the length of the transmission line.
Conventionally, in measurement of the jitter tolerance of the electronic device 3000, the deterministic jitter generated by the transmission line during propagation has not been taken into consideration. Therefore, the jitter tolerance value under the actual condition deteriorates more than the measured jitter tolerance.
Moreover, for example, some standard specifies a relatively long transmission line, which might be connected to the electronic device 3000 conventionally. In this conventional measurement case, since the transmission line injects the deterministic jitter into the input signal, the measured bit error rate and the jitter tolerance are suffered from this additional deterministic jitter. That is, the estimated bit error rate or the jitter tolerance value of the system includes both the effects of transmission line and the BER or the jitter tolerance value of the electronic device. However, the measured result has been regarded as the bit error rate and the jitter tolerance of the electronic device 3000 only. Therefore, the bit error rate and jitter tolerance of the electronic device 3000 has not been able to be measured with sufficient accuracy.
The measuring apparatus 100 in this example measures the jitter tolerance with the effects of the deterministic jitter being excluded, and the jitter tolerance including the effects of the deterministic jitter. Therefore, the jitter tolerance of the system, which includes a long transmission line causing the deterministic jitter under the actual conditions, can be measured. Moreover, the jitter tolerance of only the electronic device 3000 can be measured with sufficient accuracy. For example, even if it is tested in the environment where the length of transmission lines differ, the repeatable test of the jitter tolerance of the electronic device 3000 can be performed.
For example, as shown in
The input signal generating unit 388 generates the input signal which is input into the electronic device 3000. The input signal is a digital signal which includes a desired pattern. Moreover, the input signal generating unit 388 applies a desired input timing jitter on the input signal. That is, the input signal generating unit 388 has similar function to the signal input means 301 described with reference to
The input signal is input into the electronic device 3000 through a transmission line, and the electronic device 3000 outputs the output signal corresponding to the input signal. In this example, the length of the transmission line is shorter than a predetermined length thereby the transmission line does not inject into the input signal being transmitted. Alternatively, the output signal may be the recovered clock described with reference to
The jitter transfer function measuring apparatus 101 and the jitter related transmission penalty estimator 4102 include the same or similar function and configuration as/to those of the jitter transfer function measuring apparatus 101 described with reference to
Here, the jitter tolerance inf(Δθpp) of the system including the transmission line and the electronic device 3000 is expressed by the following Equation.
Where, Δτpp(l) is the deterministic jitter in the input signal when the signal is transmitted through a transmission line which has length 1. That is, the first term of the right-hand side of Equation (65) gives the jitter tolerance of the electronic device, and the second term of the right-hand side gives the quantity of the degradation of the jitter tolerance deteriorated in the transmission line by the deterministic jitter.
Moreover, when the transmission line is shorter than a predetermined length lth, the quantity of the degradation of the jitter tolerance by the deterministic jitter in the input signal transmitted in the transmission line is negligible. Therefore, the jitter tolerance inf(Δθpp) of the system can be expressed by the following Equation.
Where, u(l) is a unit-step function, which is one when 1 is greater than zero, and is zero when 1 is equal to or less than zero.
Moreover, the jitter tolerance inf(Δθpp) of the system can be expressed by the following Equation.
Where, ΔθMOD is equal to or substantially equal to 0.5 UI.
The jitter tolerance degradation quantity estimator 390 estimates the quantity of the jitter tolerance caused by the degradation of the deterministic jitter in the input signal transmitted through the transmission line based on the input signal. That is, the jitter tolerance degradation quantity estimator 390 estimates the second term of the right-hand side of Equation (65), Equation (66), or Equation (67). The detail of estimation of the quantity of degradation will be described hereinafter with reference to
In this example, the jitter tolerance degradation quantity estimator 390 estimates the quantity of jitter tolerance degradation in the long transmission line during use. At this time, the pattern of the input signal, the property of the long transmission line per unit length, and the length of the long transmission line during use of the electronic device 3000 are input into the jitter tolerance degradation quantity estimator 390, thereby the quantity of jitter tolerance degradation by the deterministic jitter of the long transmission line during use will be estimated based on the result.
The system jitter tolerance estimator 392 estimates the jitter tolerance of the system including the long transmission line and the electronic device 3000 during use by correcting the jitter tolerance estimated by the jitter tolerance estimator 302 based on the quantity of jitter tolerance degradation estimated by the jitter tolerance degradation quantity estimator 390. For example, the jitter tolerance of the system is estimated using Equation (65), Equation (66), and Equation (67).
Moreover, even if the measuring apparatus 100 connects the long transmission line, which causes the deterministic jitter, to the electronic device 3000 at the time of the test of the electronic device 3000, it can estimate the jitter tolerance of the system including the long transmission line and the electronic device 3000 during use. In this case, the jitter tolerance degradation quantity estimator 390 estimates the difference between the deterministic jitter in the transmission line at the time of the test and the deterministic jitter in the transmission line during use. Then, the system jitter tolerance estimator 392 corrects the jitter tolerance estimated by the jitter tolerance estimator 302 computed based on the difference. When measuring the jitter tolerance of only the electronic device 3000 via the transmission line causing the deterministic jitter at the time of the test of the electronic device 3000, the jitter tolerance degradation quantity estimator 390 estimates the quantity of jitter tolerance degradation in the transmission line at the time of the test, and the system jitter tolerance estimator 392 functions as a device jitter tolerance estimator which estimates the jitter tolerance of the electronic device 3000 based on the jitter tolerance of the electronic device 3000 estimated by the jitter tolerance estimator 302 and also based on the quantity of jitter tolerance degradation estimated by the jitter tolerance degradation quantity estimator 390. In this case, the device jitter tolerance estimator computes the jitter tolerance of the first term of the right-hand side using Equation (64), Equation (65), and Equation (66).
Moreover, although the jitter tolerance estimator 302 estimates the jitter tolerance based on the gain, phase, or jitter distortion of the jitter transfer function in this example, the bit error rate estimator 102 may directly detect the bit error of the output signal, and the jitter tolerance estimator 302 may estimate the amplitude of the input timing jitter, by which the bit error rate estimator 102 detects the bit error, as the jitter tolerance in another example. In this case, the input signal generating unit 388 sequentially inputs a plurality of input signals, on which the input timing jitter having increasing amplitude is applied, into the electronic device 3000, and the jitter tolerance estimator 302 detects the amplitude of the input timing jitter by which the bit error is detected.
An example of operation of the bit error rate estimator 102 in this case will be explained hereinafter.
When the electronic device 3000 is a deserializer as shown in
Next, the digitized signal is binarized by a comparator means or the like, and the binarized parallel signal is sampled at the rising edge of the digitized recovered clock. A generated binary series and the reference pattern signal are compared with each other, and then the bit error is detected.
Incidentally, in a 15-stage PRBS (pseudo random binary sequence), there exists at least one portion where consecutive “1” bits form the run, which has length 15, in a serial bit stream. Therefore, the binary series and the standard PRBS are aligned with each other by pattern matching the portion corresponding to such maximum length. Finally, the error of the binary series is detected by comparing them bit-by-bit.
The input signal spectrum estimator 394 receives the input signal to be input into the transmission line from the input signal generating unit 388, and estimates the spectrum of the input signal. The transmission line property estimator 396 estimates transmission property in the transmission line for every frequency band. For example, it is preferable that the transmission line property estimator 396 stores the transmission property per unit length in advance for every kind of the transmission line. In this case, the kinds and lengths of the transmission lines are input into the transmission line property estimator 396, and the transmission property in the transmission line is estimated based on the kinds and lengths of the transmission line.
The deterministic jitter estimator 398 estimates the jitter tolerance deteriorated due to the deterministic jitter in the input signal transmitted through the transmission line based on the spectrum of the input signal estimated by the input signal spectrum estimator 394 and the transmission property of the transmission line. The deterministic jitter can be estimated because the quantity of delay of each edge of the input signal can be estimated based on the spectrum component of the input signal and the passage property for every frequency band of the transmission line. Moreover, the deterministic jitter estimator 398 may estimate the peak value of the amplitude of the deterministic jitter as the quantity of jitter tolerance degradation.
Moreover, in another example of the jitter tolerance degradation quantity estimator 390, the quantity of jitter tolerance degradation can be estimated by the deterministic jitter caused in the input signal which is transmitted through the transmission line by comparing the input signal input into the transmission line from the input signal generating unit 388 with the input signal input into the electronic device 3000 from the transmission line. The quantity of jitter tolerance degradation caused in the transmission line can be estimated by comparing the signal input into the transmission line with the signal output from the transmission line.
Next, in S4302, the amplitude of the input timing jitter applied on the input signal is set. Then, in S4304, it is detected whether there is a bit error in the output signal output from the electronic device in response to the input signal.
When a bit error is not detected in the output signal, the amplitude of the input timing jitter is made to increase and S4302-S4306 are repeated. When a bit error is detected in the output signal, the amplitude of the input timing jitter at this time is defined as the jitter tolerance (S4308). As mentioned above, the measuring apparatus 100 estimates the jitter tolerance of the system and the jitter tolerance of the electronic device 3000 at the frequency of the input timing jitter.
Then, it is judged whether there remains any frequency band to be tested (S4310), and the process ends when the jitter tolerance is computed about all the jitter frequencies that are to be tested. When there remains the jitter frequency to be tested, the steps of S4300-S4310 will be repeated.
By the above-mentioned steps, at all the frequencies of the input timing jitter, the jitter tolerance of the system, and the jitter tolerance of the electronic device 3000 can be estimated.
Although the present invention has been described by way of exemplary embodiments, it should be understood that those skilled in the art might make many changes and substitutions without departing from the spirit and the scope of the present invention which is defined only by the appended claims. Also, it should be understood that the measuring apparatus and measuring method of the present invention might also measure or test network system including optical devices. That is, network system including circuits, electronic devices, optical devices, and other systems may be included in the scope of the electronic device of the present invention which is defined only by the appended claims. Moreover, circuits, electronic devices, and systems, which include devices such as optical devices inside, may be included in the scope of the electronic device of the present invention which is defined only by the appended claims.
As is apparent from the above, according to the present invention, the jitter transfer function, the bit error rate and the jitter tolerance of the DUT can be calculated efficiently. Moreover, the system jitter tolerance including the influence of the deterministic jitter and the device jitter tolerance which does not include the influence of the deterministic jitter can be measured easily.
Claims
1. A measuring apparatus for measuring reliability against jitter of an electronic device, comprising:
- a jitter tolerance estimator operable to estimate a jitter tolerance of the electronic device based on an output signal output from the electronic device according to an input signal input through a transmission line which does not generate a deterministic jitter;
- a jitter tolerance degradation quantity estimator operable to estimate a quantity of degradation of the jitter tolerance which deteriorates by the deterministic jitter caused in the input signal due to transmission through the long transmission line when the input signal is input into the electronic device through the long transmission line which causes the deterministic jitter;
- a system jitter tolerance estimator operable to estimate a jitter tolerance of a system including the long transmission line and the electronic device based on a jitter tolerance of the electronic device and also based on quantity of degradation of the jitter tolerance.
2. The measuring apparatus as claimed in claim 1, further comprising:
- a timing jitter estimator operable to estimate an output timing jitter sequence of the output signal based on the output signal; and
- a jitter transfer function measuring apparatus operable to measure the jitter transfer function in the electronic device based on the output timing jitter sequence, wherein
- said jitter tolerance estimator estimates a jitter tolerance of the system based on a gain of the jitter transfer function.
3. The measuring apparatus as claimed in claim 2, wherein said jitter tolerance estimator estimates a jitter tolerance of the system further based on a phase of the jitter transfer function.
4. The measuring apparatus as claimed in claim 1, further comprising:
- a timing jitter estimator operable to estimate an output timing jitter sequence of the output signal based on the output signal; and
- a jitter distortion estimator operable to estimate a jitter distortion of a timing jitter of the output signal based on the output timing jitter sequence, wherein
- said jitter tolerance estimator estimates a jitter tolerance of the system based on the jitter distortion.
5. The measuring apparatus as claimed in claim 4, wherein said jitter distortion estimator estimates the jitter distortion based on a spectrum of a timing jitter of the output signal.
6. The measuring apparatus as claimed in claim 2, wherein said timing jitter estimator comprises:
- an instantaneous phase noise estimator operable to calculate an instantaneous phase noise of the output signal based on the output signal; and
- a resampler operable to generate said output timing jitter sequence obtained by resampling the instantaneous phase noise at predetermined timings.
7. The measuring apparatus as claimed in claim 6, wherein said instantaneous phase noise estimator comprises:
- an analytic signal transformer operable to transform the output signal to a complex analytic signal;
- an instantaneous phase estimator operable to estimate an instantaneous phase of the analytic signal based on the analytic signal;
- a linear instantaneous phase estimator operable to estimate a linear instantaneous phase of the output signal based on an instantaneous phase of the analytic signal; and
- a linear trend remover operable to calculate an instantaneous phase noise obtained by removing the linear instantaneous phase from the instantaneous phase based on the instantaneous phase and the linear instantaneous phase.
8. The measuring apparatus as claimed in claim 2, wherein said timing jitter estimator comprises:
- a period jitter estimator operable to estimate a period jitter sequence of the output signal;
- an ideal edge timing estimator operable to estimate average period of the period jitter sequence; and
- an edge timing error estimation unit operable to estimate the output timing jitter sequence based on the average period of the period jitter sequence and the period jitter sequence.
9. The measuring apparatus as claimed in claim 1, further comprising an input signal generating unit operable to generate the input signal to which a plurality of timing jitters are applied, wherein frequencies of the timing jitters are different from one another.
10. The measuring apparatus as claimed in claim 1, further comprising a bit error rate estimator operable to detect a bit error of the output signal based on the output signal of the electronic device, wherein
- said input signal generating unit sequentially inputs the plurality of input signals on which the timing jitters are applied into the electronic device, wherein the amplitudes of the timing jitters are different from one another, and
- said jitter tolerance estimator estimates a peak-to-peak value of the timing jitter, in which said bit error rate estimator does not detect a bit error of the output signal, as the jitter tolerance.
11. The measuring apparatus as claimed in claim 10, wherein said bit error rate detector detects the bit error by sampling the data signal output from the electronic device outputs by a clock signal output by the electronic device, detecting each bit of the data signal, and comparing each bit of the detected data signal with each bit of the given reference signal.
12. A measuring apparatus for measuring reliability against jitter of an electronic device, comprising:
- a jitter tolerance estimator operable to estimate a jitter tolerance of a system including a predetermined transmission line and the electronic device based on an output signal output from the electronic device according to an input signal input through the transmission line;
- a jitter tolerance degradation quantity estimator operable to estimate a quantity of jitter tolerance degradation based on the input signal, wherein the jitter tolerance degradation is caused by a deterministic jitter generated in the input signal due to a transmission through the transmission line; and
- a device jitter tolerance estimator operable to estimate a jitter tolerance of the electronic device by correcting a jitter tolerance of the system estimated by said jitter tolerance estimator based on the quantity of jitter tolerance degradation estimated by said jitter tolerance degradation quantity estimator.
13. The measuring apparatus as claimed in claim 12, further comprising an input signal generating unit operable to generate the input signal and provides an input signal to the electronic device through the transmission line, wherein
- said jitter tolerance degradation quantity estimator compares the input signal input into the transmission line from said input signal generating unit with the input signal input into the electronic device from the transmission line, and estimates the quantity of jitter tolerance degradation by the deterministic jitter based on the comparison result.
7012982 | March 14, 2006 | Basch et al. |
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Type: Grant
Filed: Aug 25, 2004
Date of Patent: Dec 4, 2007
Patent Publication Number: 20050267696
Assignee: Advantest Corporation (Tokyo)
Inventors: Takahiro Yamaguchi (Tokyo), Masahiro Ishida (Tokyo), Mani Soma (Seattle, WA)
Primary Examiner: Emmanuel Bayard
Attorney: Osha Liang LLP
Application Number: 10/925,870
International Classification: H04B 3/46 (20060101);